# How environment and genetic architecture of unreduced gametes shape the establishment of autopolyploids

**Authors:** Yu Cheng, Filip Kolář, Roswitha Schmickl, Josselin Clo

PMC · DOI: 10.1038/s41437-025-00816-3 · 2026-01-13

## TL;DR

The study explores how environmental changes and genetic factors influence the formation and survival of autopolyploids in plant populations.

## Contribution

A novel theoretical model linking unreduced gamete production and environmental adaptation explains the establishment of autopolyploids.

## Key findings

- Adaptation to new environments is primarily driven by diploid populations rather than tetraploid persistence.
- Mixed-ploidy populations can form under certain genetic and environmental conditions.
- Pleiotropy and environmental effects support coexistence of diploid and tetraploid cytotypes.

## Abstract

It is broadly assumed that polyploidy success results from increased fitness associated with whole genome duplication due to higher tolerance to stressful conditions. In agreement, several theoretical models found that, among other factors, a better tolerance to new environmental conditions can promote polyploidy establishment. Here, we investigated the effect of the genetic and environmental factors affecting the architecture of unreduced gamete production, to see how it affects the origin and persistence of autopolyploids in both stable and disturbed environments. We developed a theoretical model in which we modeled the joint evolution of a quantitative trait under selection and the production of unreduced gametes; both traits were pleiotropically linked. We followed the adaptation of initially diploid populations to a new environment to which tetraploid individuals were directly adapted. The generation of these autotetraploid individuals was enabled by the genetic production of unreduced gametes and by the environmental change modifying the average production of these gametes. We found that for realistic values of unreduced gamete production adaptation to new environmental conditions was mainly achieved through adaptation of diploids to the new optimum rather than the persistence of newly adapted tetraploid individuals. In broader parameter sets, we found that the adaptation process led to mixed-ploidy populations, except when the populations were swamped with unreduced gametes, and that pleiotropy and environmental effects favored the co-existence of both cytotypes.

## Full-text entities

- **Genes:** RBR1 (retinoblastoma-related 1) [NCBI Gene 820408] {aka ATRBR1, RB, RB1, RBR, RETINOBLASTOMA 1, RETINOBLASTOMA PROTEIN}, PS1 (forkhead-associated (FHA) domain-containing protein) [NCBI Gene 840337] {aka ATPS1, PARALLEL SPINDLE 1}, MPK4 (MAP kinase 4) [NCBI Gene 828151] {aka ATMPK4, F2N1.1, F2N1_1, MAP kinase 4, MAPK4}, TES (ATP binding microtubule motor family protein) [NCBI Gene 823396] {aka ARABIDOPSIS NPK1-ACTIVATING KINESIN 2, ATNACK2, NACK2, NPK1-ACTIVATING KINESIN 2, TETRASPORE}, SWI1 (SWITCH1) [NCBI Gene 835207] {aka DYAD, MFG13.3, MFG13_3, SWITCH1}
- **Diseases:** WGD (MESH:C531766)
- **Chemicals:** UG (-)
- **Species:** Trifolium pratense (peavine clover, species) [taxon 57577], Petunia sp. (species) [taxon 4104], Arabidopsis thaliana (mouse-ear cress, species) [taxon 3702]

## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12891648/full.md

---
Source: https://tomesphere.com/paper/PMC12891648